US20050229734A1 | 2005-10-20 | |||
JPH0285522A | 1990-03-27 | |||
US2564019A | 1951-08-14 | |||
US3754781A | 1973-08-28 | |||
DE102006006008A1 | 2007-08-16 | |||
DE19939729A1 | 2001-02-22 | |||
DE102009007957A1 | 2010-08-19 | |||
DE19913693A1 | 2000-09-28 |
Claims 1 . A torque transmitting shaft connection comprising a drive member and a driven member on a drive axis, one of said members comprising a collet adapted to receive the other of said members, the other of said members having a circumferential groove, the collet fingers each having an inwardly directed protrusion for engagement in said groove, and a closure member movable along said axis being provided to close the collet to grip the other member for transmission of torque. 2. A connection according to claim 1 , wherein one of said members is tubular, and said collet is integrally formed therewith. 3. A connection according to claim 1 or claim 2, wherein the fingers of the collet are tapered. 4. A connection according to any preceding claim, wherein each said protrusion is adjacent the tip of a respective finger. 5. A connection according to any preceding claim, wherein in the relaxed condition, the radially innermost diameter defined by the protrusions is less than the diameter of the member to be received therein. 6. A connection according to any preceding claim, wherein the closure member is a nut. 7. A connection according to claim 6 as dependent upon claim 3, wherein said nut is internally tapered to mate with said fingers. 8. A connection according to claim 6 or claim 7, wherein said collet is externally threaded at an axial distance from the inward protrusions of the collet fingers. 9. A connection according to any of claims 6-8, wherein said nut includes an axial portion of constant internal diameter around the other of said members. 10. A connection according to claim 9, wherein said axial portion includes a recess adapted to receive a seal. 1 1 . A connection according to claim 10, wherein said recess comprises a circumferential channel intermediate the axial ends of the nut. 12. A connection according to claim 1 1 , wherein said channel is adapted to contain an O ring. 13. A connection according to any preceding claim, wherein said circumferential groove is arcuate. 14. A connection according to claim 13, wherein the protrusions of said collet fingers are arcuate. 15. A torque transmitting shaft connection comprising a drive member and a driven member on a drive axis, one of said members comprising a collet adapted to receive the other of said members, the connection further comprising a resilient member located between the drive member and the driven member, and a closure member movable along said axis being provided to close the collet to grip the other member for transmission of torque. 16. A connection according to any of claims 1 -14, the connection further comprising a resilient member located between the drive member and the driven member. 17. A connection according to claim 16 or claim 17, wherein the resilient member is located between the collet of one member and the other of said members. 18. A connection according to claim 17, wherein the resilient member comprises an O ring located around the other of said members. 19. A connection according to any of claims 15-18, wherein at least one of the drive member and the driven member comprise a recess adapted to receive the resilient member. 20. A connection according to claim 19, wherein a plurality of the fingers of the collet comprise a recess adapted to receive the resilient member. 21 . A connection according to any of claims 15-20, wherein the connection comprises a plurality of resilient members located between the drive member and the driven member. 22. A vehicle having a connection as claimed in any preceding claim. 23. A connection or a vehicle constructed and/or arranged substantially as described herein with reference to figure 2 of the accompanying drawings. |
This invention relates to a shaft connection , and particularly but not exclusively to a connection adapted to transmit torque, such as in a driveline of a vehicle. Aspects of the invention relate to a connection and to a vehicle.
Many kinds of torque transmitting shaft connection are known. For example a motor vehicle driveline may include a propeller shaft comprising an axially immovable connection at one end; the other end may plunge to accommodate axle movement, but this invention is not concerned with that end.
A typical connection at the axially fixed end comprises circular flanges of the propeller shaft and the next driveline component, which may be an input shaft of an axle. The propeller shaft is usually a steel tube to which the associated flange is attached by welding. The flange of the input shaft may be a separate annular component immovably fixed to the input shaft by a nut or the like. Each flange is provided with a plurality of equi-spaced holes on a diameter thereof, and the flanges are coupled by nuts and bolts, sometimes with spring or plain washers. One coupled, the flanges are immovable both axially and in relative rotation, and can effectively transmit torque.
This kind of flange connection is extremely well-known, and has the advantage of being well understood, of simple construction, and straightforward to assemble and dismantle. After removal of the nuts and bolts, the flange connection generally separates without difficulty. It is of great importance that such a connection, of whatever kind, should transmit torque without relative rotational movement play or relative axial movement. Any such movement causes noise and vibration, and may lead to failure of the connection in service.
Flange connections also have disadvantages. The flange must be provided and attached to the components to be joined. Generally four or more nut/bolt pairs are required to be assembled, and moreover the flange must be aligned and held in alignment whilst the first bolts are inserted. The nuts and bolts constitute loose parts which may become mislaid or lost. Upon assembly each nut/bolt pair must be reliably torqued to the correct tightness. Flanged connections are relatively heavy, and moreover have a relatively large diameter which is generally significantly larger than the diameter of the shafts to be connected. Reduction in flange size is not easy because the bolts require to be of a certain diameter for strength, and access is required for tools and hands. As a consequence the clearance between the shafts and neighbouring vehicle parts is relatively great.
Finally, upon making a connection, it is not unusual to have to rotate the shafts in order to give access to all of the nut/bolt pairs. This may require special measures if the shafts are substantially immovable in the rest condition.
The disadvantages described above are typical of a motor vehicle propeller shaft connection. The problems are generally applicable to all such flange connections whether in a motor vehicle driveline, or elsewhere.
What is required is an improved shaft connection that can ameliorate some or all of the disadvantages of a flanged shaft connection. According to one aspect of the invention there is provided a torque transmitting shaft connection comprising a drive member and a driven member on a drive axis, one of said members comprising a collet adapted to receive the other of said members. The connection further comprises a first resilient member located between the drive member and the driven member, and a closure member movable along said axis being provided to close the collet to grip the other member for transmission of torque.
In such an arrangement both the collet and closure member may have a relatively low profile so that the diameter of the connection is substantially less than a prior art flanged joint. The closure member may be unitary, and may replace the plurality of nuts and bolts. The resilient member provides resistance against movement of the drive member with respect to the driven member, in particular radial movement with respect to the drive axis.
The resilient member may be formed from a plastic material, rubber, silicon, metal or any suitable material which is capable of elastic deformation.
Typically, the first resilient member is located between the collet of one member and the other of said members. It may be that the resilient member is located between the fingers of the collet of one member and the other of said members. It may be that the resilient member comprises an O ring located around the other of said members. It may be that at least one of the drive member and the driven member comprise a recess adapted to receive the resilient member. The recess may comprise a groove. The recess may be arcuate. The recess may be circumferential around the drive member or the driven member.
It may be that a plurality of the fingers of the collet comprise a recess adapted to receive the resilient member.
It may be that the connection further comprises a plurality of resilient members located between the drive member and the driven member.
It may be that the other of said members has a circumferential groove, the collet fingers each having an inwardly directed protrusion for engagement in said groove.
According to a second aspect of the invention there is provided a torque transmitting shaft connection comprising a drive member and a driven member on a drive axis, one of said members comprising a collet adapted to receive the other of said members, the other of said members having a circumferential groove, the collet fingers each having an inwardly directed protrusion for tight engagement in said groove, and a closure member movable along said axis being provided to close the collet to grip the other member for transmission of torque.
In such an arrangement both the collet and closure member may have a relatively low profile so that the diameter of the connection is substantially less than a prior art flanged joint. The closure member may be unitary, and may replace the plurality of nuts and bolts. The inwardly directed protrusions may provide a positive axial lock to ensure against relative axial movement of the drive and driven members.
In one embodiment one of said members is tubular, and said collet is integrally formed therewith. Thus a tubular propeller shaft may have collet fingers machined at the end thereof by turning and slotting. Typically three to six such fingers are provided. The fingers are tapered in one embodiment.
In one embodiment the collet fingers are resilient, and in the free condition define an internal diameter slightly less than the outer diameter of the other member. I n one embodiment each protrusion is adjacent the end of a respective finger, and the radially innermost diameter thereof is slightly less than the diameter of the shaft to be received in the collet. I n this way, for assembly purposes, the collet and shaft may be assembled with friction, and the protrusions will spring into the circumferential groove at the desired insertion depth, thus loosely retaining the parts in the correct relative axial position whilst the closure member is subsequently closed. This arrangement avoids the need for other measures for ensuring the correct insertion depth, such as lining up external markings.
The closure member is in one embodiment a nut having a threaded interior for engagement with a threaded portion of the collet; this threaded portion is distal of the tapered fingers. In one embodiment the nut is tapered internally to match the taper of the collet fingers in the closed condition. A sliding, snap-fitting closure member, or a circumferential clamp are examples of alternative closure members. The closure member may have a plain portion to accommodate a seal for the adjacent shaft, which may for example be a lip seal or an O ring.
Within the scope of this application it is envisaged that all of the various aspects, embodiments examples, features and alternatives set out in the preceding paragraphs, in the claims and/or in the following description and drawings may be taken independently or in any combination thereof. For example, features described in connection with one embodiment are applicable to all embodiments unless there is incompatibility of features.
Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings in which:-
Fig. 1 is an illustration of a prior art flange connection; and
Fig. 2 is an axial section through a shaft connection according to an embodiment of the invention.
With reference to Fig. 1 , a known propeller shaft connection comprises a tubular propeller shaft (1 1 ) having a circular flange (12) welded to the end thereof. An input shaft (13) of an axle (not shown) has a circular flange (14) attached thereto, typically by a spline or keyway arrangement. The flanges are pierced i n a regu lar fashion on centreli nes ( 1 5) to accommodate nuts and bolts whereby the flange can be tightly coupled for rotation about axis (16) without relative axial or rotational movement. In order to couple the flanged connection of Fig. 1 , the components must be supported in rotational and axial alignment whilst the bolts are inserted. Surrounding structure may require rotation of the connection to permit all of the nut/bolt pairs to be tightened individually.
With reference to Fig. 2, the connection of the invention is illustrated. A tubular propeller shaft (21 ) is directly machined at the free end to define an external screw thread (22) and a plurality of tapered collet fingers (23). The number of collet fingers is not material, but may for example be between three and six. The radially external face of the fingers has a straight taper, as illustrated, which merges immediately into the screw thread at the major diameter thereof.
On the inner side each finger (23) has a radially inwardly directed projection (24), which may be formed by machining, by upsetting or in any other convenient manner. Each projection may extend around the full circumferential arc of a respective finger, or may comprise single or multiple protrusions. As illustrated each projection has a generally arcuate form in the axial direction.
Although an integrally machined collet is described, it could of course be a separate component attached in any suitable manner to the drive shaft.
A driven shaft (31 ) comprises a plain diameter with a single circumferential groove (32) of arcuate form. Such a groove can be easily machined along with other radial features (not shown) of the shaft.
The collet further comprises a recess 61 in the form of a circumferential groove, into which is fitted an O ring 62 which then encloses the driven shaft 31. The O ring is formed from a resilient material which is capable of elastic deformation. The depth of the recess 61 is less than the diameter of the O ring 62 such that when the connection is assembled the O ring is elastically deformed and exerts pressure on the inner surface of the recess 61 and on the driven shaft 31.
Once the connection is assembled, in order the drive member or the drive member to move radially with respect to the drive axis, the drive member must also tilt with respect to the driven member. This motion is minimised where the collet is tightly fitted, however over time sufficient "play" may develop to allow radial movement. The O ring tends to resist such motion, since it would require a further deformation of the O ring. Hence radial movement is minimised.
A collet nut (41 ) surrounds the shaft (31 ) and includes both a threaded portion (42) for engagement with the screw thread (22), and an internally tapered portion (43) for engagement with the external tapered faces of the collet fingers. A plain diameter portion (44) at the opposite end to the threaded portion (42) is internally grooved to contain an O ring seal (45). For assembly purposes the nut (41 ) may be loosely retained on the shaft (31 ) by any suitable means.
In the unassembled condition, the collet fingers (23) are arranged to be a light resilient sliding fit on the shaft (31 ). The arcuate form of the projections (24) ensures that the shaft (31 ) can be easily inserted, but with slight resistance to axial movement. Upon reaching the groove (32), the projections spring radially inwardly to hold the components against relative movement, and in this condition the shafts (21 , 31 ) are retained without the need for other measures.
The nut (41 ) is then slid axially along the shaft (31 ), and the threaded portion (42) engaged with the screw thread (22). Upon tightening, the nut draws the collet fingers (23) tightly onto the shaft (31 ) to give a shaft connection without relative axial or rotational movement. The seal (45) prevents ingress of moisture, which may cause corrosion. The projections are designed to fit tightly within the groove (32) in the assembled condition.
Disassembly is the reverse procedure and the collet fingers spring outwardly due to their inherent resilience; it will be appreciated that the nut can be fully disengaged without the connection falling apart, as would happen in a flanged joint when the last bolt is removed.
Fastening and unfastening of the nut is possible from one side (such as the underside of a vehicle), and other components can be mounted more closely to the joint. A substantial weight saving is possible, up to 1 .5 kg, and balancing of the propeller shaft may be obviated since the prior art welded connection is eliminated.
Should it be necessary, the external surface of the nut may be used to locate an external boot or the like for shrouding the connection, as indicated by the dotted line (51 ). Such a boot may be clamped externally and and/or accommodated in a groove of the nut, and is desirable if, for example, the connection is adjacent a device within which oil or grease must be retained. One example of such a device is an articulating drive joint of a front-wheel drive vehicle.
In the example described, the component material is steel. However it will be understood that other materials are possible dependent upon the nature and duty of the connection. The skilled man will be able to define sizes and dimensions suitable for transmission of the desired torque, which in a motor vehicle may be in the range 200-1000 Nm.
In a second embodiment, the collet may comprise further recesses, into each of which is fitted a further O ring. The further O rings can then provide additional resistance to radial movement.
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